A. M. Babakr, A. Al-Ahmari, K. Al-Jumayiah, F. Habiby
Saudi Basic Industries Corporation (SABIC)SABIC Technology Center-Jubail, P.O. Box 11669, Al-Jubail, 31961 Saudi Arabia.
DOI: 10.4236/jmmce.2008.72011   PDF    HTML     14,616 Downloads   22,225 Views   Citations

Abstract

HK alloy is a member of the heat resistant cast alloy family (H-Series) steels. They are widely used in the petrochemical industry for components requiring enhanced high temperature properties. Microstructural changes occurring at high temperature clearly affects its mechanical properties. These properties have been shown in HK-40 steel subjected to high-temperature degradation and prone to the formation of sigma phase. The investigation carried out included metallurgical analysis, materials characterization and mechanical analysis. Metallurgical analysis included advanced metallography techniques to characterize its microstructure morphology and properties. Significant depletion of vital precipitates observed that definitely degraded its high temperature properties. Mechanical analysis included hardness profile, tensile testing of samples taken from the tree supports and tested in room temperature and in 800°C environments. Experimental results revealed that the structure of HK-40 affected by the formation of the high temperature brittle sigma-s-phase. Nonetheless, mechanical properties did not suffer much at higher temperature.

Keywords

Sigma-phase, Corrosion; Microstructure; Heat resistant steels; Hardness

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Conflicts of Interest

The authors declare no conflicts of interest.

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